JP2009272540A - Electronic instrument - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To prevent radiation noise radiated from a wiring pattern due to resonance generated in the wiring pattern on a circuit board which has received the radiation noise. <P>SOLUTION: In an image reading device operated in accordance with a driving signal of a predetermined frequency, an original illumination board 707a having a wiring pattern formed of a conductor is provided and inductances 105-119 are provided with spaces Ln of not longer than a predetermined length on the wiring patterns 120-124 longer than a predetermined length which generates resonance by the driving signal of the predetermined frequency. <P>COPYRIGHT: (C)2010,JPO&INPIT

Description

  The present invention relates to an electronic device that operates in response to a drive signal having a predetermined frequency.

  Some image reading apparatuses such as conventional copying machines read a document by moving and scanning a reading unit including a light source and an image sensor (see, for example, Patent Document 1). The reading unit is connected to the image signal receiving unit via a flexible flexible cable that is an image signal transmitting means. Since the image reading apparatus having such a structure has an advantage that the thickness of the apparatus can be suppressed, it is suitable for a small apparatus.

  However, the reading unit may be in an electrically floating state, and a drive signal for the image sensor of the reading unit may cause radiation noise. A large current is required for the drive signal for driving the light source and the image sensor, and a high-frequency signal is used to realize high-speed reading. Therefore, radiation noise occurs between the IC that drives them and the reading unit.

As a countermeasure against such radiation noise, a method of applying an electrostatic shield to a flexible cable or the like, and a method of forming a platen glass with a conductive transparent member have been proposed (Patent Document 2).
JP-A-8-195860 JP-A-2-308667

  Such a countermeasure is effective for radiation noise generated from the flexible cable, but is not effective for radiation noise generated from the reading unit itself.

  In addition, conductive platen glass is generally coated with a conductive coating of several microns on the glass surface, and it easily wears and peels off due to the placement of the manuscript, which radiates at an increased cost. Noise suppression effect does not last.

  Furthermore, as a cause of radiation noise, resonance may occur on the wiring pattern due to the relationship between the length of the wiring pattern on the circuit board of the reading unit and the frequency of the radiation noise, and the wiring pattern may become an antenna that radiates radiation noise. is there.

  An object of the present invention is to prevent the occurrence of resonance in a wiring pattern on a circuit board that has received radiation noise, and the radiation noise being radiated from the wiring pattern.

  In order to solve the above problems, the present invention provides a circuit board having a wiring pattern formed of a conductor in an electronic device that operates in response to a drive signal having a predetermined frequency, and resonance is generated by the drive signal having the predetermined frequency. The present invention provides an electronic device characterized in that impedance elements are provided at intervals less than the predetermined length for a wiring pattern having a predetermined length or longer.

  According to the present invention, since impedance elements are provided at intervals less than a predetermined length for the wiring pattern, resonance can be prevented from occurring on the wiring pattern, and radiation noise due to resonance is radiated from the wiring pattern. Can be prevented.

(First embodiment)
FIG. 1 is a diagram illustrating a configuration of an image reading apparatus according to an embodiment of the present invention. 1A is a top view, and FIG. 1B is a cross-sectional view. An outer frame is constituted by a casing upper frame 701 and a casing lower frame 709 which are conductive members. A document table glass 710 is provided in the opening 700. By moving the reading unit 702 from the left side to the right side in FIG. 1A, the image of the document placed on the platen glass 710 is read.

  The reading unit 702 includes an image sensor substrate 706, original illumination substrates 707a and 707b, and reflection plates 708a and 708b. The document illumination substrates 707a and 707b expose and irradiate the document placed on the document table glass 710 during the image reading operation. The reflected light from the original is imaged on an image sensor 711 provided on the image sensor substrate 706.

  The reading unit 702 is connected to the control board 201 shown in FIG. The document illumination boards 707a and 707b are formed by linearly arranging point light sources such as LEDs on a printed wiring board in the main scanning direction, and have a length substantially equal to the length of the image reading area in the main scanning direction. The reflection plates 708a and 708b reflect and collect the light emitted from the document illumination substrates 707a and 707b toward the document on the document table glass 710. The reflection plates 708a and 708b are obtained by vapor-depositing a metal on a base material and have a length equal to or longer than that of the original illumination substrates 707a and 707b.

  The drive shaft 704 and the guide rail 705 maintain the posture of the reading unit 702 when the reading unit 702 moves in the sub-scanning direction during the image reading operation. The control board 201 is fixed to the housing lower frame 709. Both ends of the drive shaft 704 and the guide rail 705 are grounded to the housing upper frame 701 and the housing lower frame 709. The image sensor substrate 706 is provided so that the longitudinal direction thereof is orthogonal to the longitudinal directions of the drive shaft 704 and the guide rail 705.

  FIG. 2 is a functional block diagram of the image reading apparatus. An image sensor 711 mounted on the image sensor substrate 706 receives reflected light from a document irradiated and irradiated by the document illumination substrate 707, converts it into an image signal 715, and outputs it. An image signal 715 output from the image sensor 711 is converted into image data 209 by an AD converter 713 via an amplifier 712 and transmitted to the image processing circuit 204 on the control board 201 via a cable 703. The image processing circuit 204 performs predetermined image processing such as γ correction on the input image data 209 and transmits the image data after image processing to an image forming apparatus (not shown) via the interface circuit 213. The image forming apparatus forms an image on a recording sheet based on the transmitted image data.

  The control circuit 205 on the control board 201 generates a reference signal 207 for driving the image sensor 711 and transmits it to the image sensor drive circuit 714 on the image sensor board 706 via the cable 703. The image sensor driving circuit 714 generates an image sensor driving signal 717 from the reference signal 207 generated by the control circuit 205 and drives the image sensor 711.

  The control circuit 205 generates the reference clock signal 208 of the AD converter 713 on the image sensor board 706 and the control signal 211 of the document illumination board 707, respectively, and the AD converter 713 and the document illumination via the cable 703. Input to the drive circuit 718. The document illumination drive circuit 718 inputs a document illumination drive signal 719 to the document illumination board 707 via the cable 720.

  The control circuit 205 also generates a reference signal 214 for controlling the reading unit driving motor 202 that moves the reading unit 702, and inputs the reference signal 214 to the motor driving circuit 212. The motor drive circuit 212 converts the reference signal 214 generated by the control circuit 205 into a motor drive signal and controls the reading unit drive motor 202.

  FIG. 3A is a circuit diagram of the document illumination board 707a, and FIG. 3B is a diagram showing a wiring pattern of the document illumination board 707a, showing a state in which the single-sided board is used. The document illumination board 707b has the same configuration as the document illumination board 707a.

  As shown in FIG. 3 (b), LED modules 101 to 104 formed of a plurality of LEDs are provided in a line in the main scanning direction on the document illumination board 707a.

  A predetermined DC voltage 120 is supplied to the LED modules 101 to 104 from the power supply circuit 133 in the document illumination drive circuit 718 on the image sensor substrate 706. The LED modules 101 to 104 are controlled to be turned on and off at a predetermined timing by document illumination drive signals 719a to 719d from the document illumination drive circuit 718. The DC voltage 120 and the document illumination drive signals 719a to 719d are connected to the cable 720 via the connector 135.

  The document illumination drive circuit 718 has individual drive circuits corresponding to the LED modules 101 to 104, respectively. These drive circuits are controlled to be turned on and off by control signals 211 a to 211 d output from the control circuit 205 on the control board 201. These drive circuits are composed of switching elements 125, 127, 129, and 131 and current limiting resistors 126, 128, 130, and 132 that determine the value of the current that flows through each LED module when the LED is turned on.

  Further, the DC voltage 120 supplied to each LED module and the document illumination drive signals 719a to 719d are connected through inductors 105 to 119 arranged at a predetermined interval. It is assumed that the inductor is made of a magnetic material.

  As shown in FIG. 3B, the inductors 105 to 119 are arranged at predetermined intervals Ln in the main scanning direction of the wiring pattern formed on the document illumination board 707a. The length Ln in the longitudinal direction of the wiring pattern partitioned by the inductor is set to a length that satisfies the following expression.

λ: Wavelength in the air with the maximum frequency in the electromagnetic wave radiation amount regulation range ε ₁ : Relative permeability μ _{1 of the} original illumination board (medium): Relative permittivity of the original illumination board (medium) Radiation noise normally generated from electronic equipment is It is regulated by electromagnetic radiation emission regulations such as VCCI (Council for Voluntary Control Standards for Information Processing Equipment), FCC (Federal Communications Commission), IEC (International Electrotechnical Commission), etc. It is desirable that λ be the wavelength of the maximum frequency regulated by this electromagnetic wave radiation amount regulation.

The reason for this will be described. The image sensor driving circuit 714 supplies an image sensor driving signal 717 (pulse signal (rectangular wave)) having a predetermined frequency f ₀ to the image sensor 711. This pulse signal (rectangular wave) contains a harmonic component, and this harmonic component causes radiation noise. When the image sensor 711 is a CCD (charge coupled device) serving as a capacitive load, the image sensor driving signal 717 requires a large current capacity and becomes a large radiation noise generation source. The image sensor board 706 is connected to the control board 201 via the cable 703, but is not grounded in the high frequency region because the cable 703 is long. Therefore, radiation noise is likely to be radiated from the image sensor substrate 706 to the outside of the substrate. Frequency of the radiation noise generated becomes a frequency f ₀ and fn (n is an integer) is its harmonic component.

  The document illumination boards 707a and 707b are connected to the image sensor board 706 by a cable 720. However, since the cable 720 is long, it is not grounded in the high frequency region. That is, the wiring pattern on the document illumination board 707 disposed in the vicinity of the image sensor board 706 that is a radiation noise source is equivalent to a floating conductor in a high-frequency region. Accordingly, depending on the relationship between the drive frequency of the image sensor 711 and the length L of the wiring pattern, resonance may occur in the wiring pattern that receives radiation noise radiated from the image sensor substrate 706. When resonance occurs in the wiring pattern, the wiring pattern functions as a half-wavelength antenna that radiates radiation noise.

  In order to prevent such a phenomenon, impedance elements (inductors 105 to 119) are provided at the above-described interval Ln on the wiring pattern provided in the vicinity of the radiation noise generation source. That is, the wiring pattern is divided into intervals Ln, and the divided wiring patterns are connected by an impedance element (inductor). Thereby, the occurrence of resonance on the wiring pattern can be prevented, and the wiring pattern can be prevented from functioning as an antenna for radiation noise.

  Although the wiring pattern length in the main scanning direction of the document illumination substrate 707 has been described as an example, if the wiring pattern length in the sub-scanning direction does not satisfy Equation 1, inductors may be provided at intervals that satisfy Equation 1. .

  Since the LED modules 101 to 104 are driven with a DC voltage, the inductors 105 to 119 do not hinder the lighting and extinguishing of the LED modules 101 to 104.

(Second Embodiment)
In the first embodiment, the inductors 105 to 119 are arranged as impedance elements, but the same effect can be obtained even if a capacitor (capacitor) is used. FIG. 4 shows a document illumination board 707a on which capacitors 405 to 419 are arranged. The document illumination board 707a in the present embodiment is a double-sided board. 4A is a circuit diagram of the original illumination board 707a, FIG. 4B is a diagram showing a wiring pattern on the surface of the original illumination board 707a, and FIG. 4C is an original illumination board 707a. It is a figure which shows the wiring pattern of the back surface. The corner C of the original illumination board 707a shown in FIG. 4B coincides with the corner C shown in FIG. The document illumination board 707b has the same configuration as the document illumination board 707a.

  The interval Ln in which the capacitors are arranged is set to a length that satisfies the condition described in the first embodiment. The DC voltage 120 and the document illumination drive signals 719a to 719d are connected to the cable 720 described in the first embodiment via the connector 430.

  One terminal of the capacitor 405 is connected to the wiring pattern of the DC voltage 120, and the other terminal is connected to the ground pattern 432 on the back surface through the through hole 405h. The wiring pattern 425 and the ground pattern 432 are grounded to the housing upper frame 701 and the housing lower frame 709. The ground side terminals of the capacitors 406 to 419 are also connected in the same manner as the capacitor 405. Thereby, resonance in the wiring pattern of the DC voltage 120 and the document illumination drive signals 719a to 719d can be prevented.

Here, if the ground pattern 432 on the back surface is formed with a uniform width and a length close to the length of the original illumination substrate 707a in the main scanning direction, resonance occurs in the ground pattern that receives radiation noise. It will occur. Therefore, the ground pattern 432 is formed into a plurality of islands, and inductors 437 to 440 are provided between the islands. This prevents resonance from occurring in each region (island) of the ground pattern. Island length Lg ₁ of the ground pattern 432 to a length that satisfies the following equation. The lengths Lg ₂ to Lg ₅ of other islands of the ground pattern 432 and the width Lgw of the ground pattern 432 are also set to satisfy the same condition as Lg ₁ .

λ: Wavelength in air having the maximum frequency in the electromagnetic wave radiation amount regulation range ε ₁ : Relative permeability μ _{1 of the} original illumination substrate (medium) ₁ : Relative permittivity of the original illumination substrate (medium) Even if the pattern receives radiation noise, resonance does not occur on the wiring pattern.

(Third embodiment)
In the first and second embodiments, the document illumination board has been described. However, by taking the same measures for the image sensor board, it is possible to prevent the occurrence of resonance in the wiring pattern of the image sensor board. FIG. 5A shows a wiring pattern of the image sensor substrate 706 in the present embodiment, and FIG. 5B shows an enlarged view of a region A in FIG.

  The wiring patterns 1101 and 1102 are provided along the outer periphery of the image sensor substrate 706, and a ground pattern 1103 is provided around the wiring patterns. The ground pattern 1103 is grounded. The wiring pattern 1101 includes a pair of parallel wiring patterns 1101a and 1101b for transmitting a control signal. The wiring pattern 1102 includes a pair of parallel wiring patterns 1102a and 1102b for transmitting a control signal.

  In this embodiment, capacitors 1106 to 1109 are provided between the wiring patterns 1101a to 1101b. Capacitors 1111 and 1113 are provided between the wiring pattern 1101a and the ground pattern 1103. Capacitors 1110 and 1112 are provided between the wiring pattern 1101 b and the ground pattern 1103. The reason why the capacitors 1106 and 1107 are provided close to each other in parallel is to provide a capacitor having a predetermined capacity.

  Here, the distance Ln between the capacitors 1110 and 1112 is a distance satisfying the following expression.

λ: Wavelength in air having the maximum frequency in the electromagnetic wave radiation amount regulation range ε ₂ : Relative magnetic permeability of image sensor substrate 706 (medium) μ ₂ : Relative permittivity of image sensor substrate 706 (medium) Thereby, image sensor substrate 706 Even if the wiring pattern receives radiation noise, resonance does not occur on the wiring pattern.

(Fourth embodiment)
In addition to the wiring pattern described above, when the reflection plates 708a and 708b are formed of a conductive member, resonance may occur in the conductive member of the reflection plate that has received radiation noise, similarly to the wiring pattern.

  FIG. 6A is a top view of the reflecting plate 708a in this embodiment, and FIG. 6B is a cross-sectional view of the reflecting plate 708b. The configuration of the reflector 708b is the same as that of the reflector 708a. On the base material 1001 of the reflecting plate 708a, reflecting surfaces 1002 to 1005 (a plurality of metal vapor-deposited films) are arranged. A metal vapor deposition film is not formed between the reflective surfaces 1002 and 1003, and the reflective surfaces 1002 and 1003 are insulated. The same applies to other reflective surfaces. The length Ln of one side of each of the reflection surfaces 1002 to 1005 is set to a length that satisfies the following formula.

λ: Wavelength in air having the maximum frequency in the electromagnetic wave radiation amount regulation range ε ₃ : Relative magnetic permeability of reflector 708 (medium) μ ₃ : Relative permittivity of reflector 708 (medium) Even if the deposited film receives radiation noise, resonance does not occur on the metallic deposited film.

(Other embodiments)
As described above, the embodiments of the present invention have been described. However, the present invention is not limited to an image reading apparatus, but an electronic apparatus that has a circuit board having a wiring pattern formed of a conductor and operates according to a drive signal having a predetermined frequency. Applicable. Even in this case, as described above, measures against radiation noise can be taken by providing impedance elements at intervals less than a predetermined length for a wiring pattern having a predetermined length or longer that causes resonance by a drive signal having a predetermined frequency. Can do. The impedance element may be an inductor inserted in series with the wiring pattern or a capacitor connected between the wiring pattern and the ground pattern.

1 is a diagram illustrating a configuration of an image reading apparatus according to an embodiment of the present invention. It is a functional block diagram of an image reading apparatus. FIG. 3 is a diagram showing a configuration of a document illumination board 707 in the first embodiment. It is a figure which shows the structure of the original illumination board | substrate 707 in 2nd Embodiment. It is a figure which shows the structure of the image sensor board | substrate 706 in 3rd Embodiment. It is a figure which shows the structure of the reflecting plate 708 in 4th Embodiment.

Explanation of symbols

101-104 LED module 105-119 Inductor 120 DC voltage (wiring pattern)
719a to 719d Document illumination drive signal (wiring pattern thereof)
405 to 419 Capacitor 405h Through hole 432 Ground pattern 706 Image sensor substrate 707a, 707b Original illumination substrate 708a, 708b Reflector

Claims (6)

In an electronic device that operates in response to a drive signal of a predetermined frequency,
A circuit board having a wiring pattern formed of a conductor;
An electronic device, wherein an impedance element is provided at an interval less than the predetermined length for a wiring pattern having a predetermined length or longer that causes resonance by the drive signal having the predetermined frequency.   The electronic device according to claim 1, wherein the impedance element is an inductor inserted in series with the wiring pattern.   The electronic device according to claim 1, wherein the impedance element is a capacitor connected between the wiring pattern and a ground pattern. An image sensor that operates according to the drive signal of the predetermined frequency and reads a document;
2. The electronic apparatus according to claim 1, wherein the circuit board includes a light source for exposing a document and a wiring pattern for turning on the light source.   The electronic apparatus according to claim 1, wherein the circuit board includes an image sensor that operates in accordance with the drive signal having the predetermined frequency and reads a document. A reflector that reflects the light from the light source toward the document;
5. The reflector according to claim 4, wherein a plurality of metal films for reflecting light are arranged and formed on the reflector, and a length of one side of the film is less than the predetermined length. Electronics.

Images